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NP-Completeness x1 x1 x2 x2 12 11 x3 x3 22 13 21 NP-Completeness x4 x4 32 23 31 33 1 Outline and Reading P and NP (§13.1) Definition of P Definition of NP Alternate definition of NP NP-completeness (§13.2) Definition of NP-hard and NP-complete The Cook-Levin Theorem NP-Completeness 2 Running Time Revisited Input size, n To be exact, let n denote the number of bits in a nonunary encoding of the input All the polynomial-time algorithms studied so far in this course run in polynomial time using this definition of input size. Exception: any pseudo-polynomial time algorithm SFO PVD ORD LGA HNL LAX DFW NP-Completeness MIA 3 Dealing with Hard Problems What to do when we find a problem that looks hard… I couldn’t find a polynomial-time algorithm; I guess I’m too dumb. NP-Completeness 4 Dealing with Hard Problems Sometimes we can prove a strong lower bound… (but not usually) I couldn’t find a polynomial-time algorithm, because no such algorithm exists! NP-Completeness 5 Dealing with Hard Problems NP-completeness let’s us show collectively that a problem is hard. I couldn’t find a polynomial-time algorithm, but neither could all these other smart people. NP-Completeness 6 Polynomial-Time Decision Problems To simplify the notion of “hardness,” we will focus on the following: Polynomial-time as the cut-off for efficiency Decision problems: output is 1 or 0 (“yes” or “no”) Examples: Does a given graph G have an Euler tour? Does a text T contain a pattern P? Does an instance of 0/1 Knapsack have a solution with benefit at least K? Does a graph G have an MST with weight at most K? NP-Completeness 7 Problems and Languages A language L is a set of strings defined over some alphabet Σ Every decision algorithm A defines a language L L is the set consisting of every string x such that A outputs “yes” on input x. We say “A accepts x’’ in this case Example: If A determines whether or not a given graph G has an Euler tour, then the language L for A is all graphs with Euler tours. NP-Completeness 8 The Complexity Class P A complexity class is a collection of languages P is the complexity class consisting of all languages that are accepted by polynomial-time algorithms For each language L in P there is a polynomial-time decision algorithm A for L. If n=|x|, for x in L, then A runs in p(n) time on input x. The function p(n) is some polynomial NP-Completeness 9 The Complexity Class NP We say that an algorithm is non-deterministic if it uses the following operation: Choose(b): chooses a bit b Can be used to choose an entire string y (with |y| choices) We say that a non-deterministic algorithm A accepts a string x if there exists some sequence of choose operations that causes A to output “yes” on input x. NP is the complexity class consisting of all languages accepted by polynomial-time non-deterministic algorithms. NP-Completeness 10 NP example Problem: Decide if a graph has an MST of weight K Algorithm: 1. 2. 3. Non-deterministically choose a set T of n-1 edges Test that T forms a spanning tree Test that T has weight at most K Analysis: Testing takes O(n+m) time, so this algorithm runs in polynomial time. NP-Completeness 11 The Complexity Class NP Alternate Definition We say that an algorithm B verfies the acceptance of a language L if and only if, for any x in L, there exists a certificate y such that B outputs “yes” on input (x,y). NP is the complexity class consisting of all languages verified by polynomial-time algorithms. We know: P is a subset of NP. Major open question: P=NP? Most researchers believe that P and NP are different. NP-Completeness 12 NP example (2) Problem: Decide if a graph has an MST of weight K Verification Algorithm: 1. 2. 3. Use as a certificate, y, a set T of n-1 edges Test that T forms a spanning tree Test that T has weight at most K Analysis: Verification takes O(n+m) time, so this algorithm runs in polynomial time. NP-Completeness 13 Equivalence of the Two Definitions Suppose A is a non-deterministic algorithm Let y be a certificate consisting of all the outcomes of the choose steps that A uses We can create a verification algorithm that uses y instead of A’s choose steps If A accepts on x, then there is a certificate y that allows us to verify this (namely, the choose steps A made) If A runs in polynomial-time, so does this verification algorithm Suppose B is a verification algorithm Non-deterministically choose a certificate y Run B on y If B runs in polynomial-time, so does this non-deterministic algorithm NP-Completeness 14 An Interesting Problem A Boolean circuit is a circuit of AND, OR, and NOT gates; the CIRCUIT-SAT problem is to determine if there is an assignment of 0’s and 1’s to a circuit’s inputs so that the circuit outputs 1. Inputs: Logic Gates: 0 1 1 0 NOT 0 1 1 1 Output: OR 1 1 0 0 1 AND NP-Completeness 15 CIRCUIT-SAT is in NP Non-deterministically choose a set of inputs and the outcome of every gate, then test each gate’s I/O. Inputs: Logic Gates: 0 1 1 0 NOT 0 1 1 1 Output: OR 1 1 0 0 1 AND NP-Completeness 16 NP-Completeness A problem (language) L is NP-hard if every problem in NP can be reduced to L in polynomial time. That is, for each language M in NP, we can take an input x for M, transform it in polynomial time to an input x’ for L such that x is in M if and only if x’ is in L. L is NP-complete if it’s in NP and is NP-hard. NP poly-time NP-Completeness L 17 Cook-Levin Theorem CIRCUIT-SAT is NP-complete. We already showed it is in NP. To prove it is NP-hard, we have to show that every language in NP can be reduced to it. Let M be in NP, and let x be an input for M. Let y be a certificate that allows us to verify membership in M in polynomial time, p(n), by some algorithm D. Let S be a circuit of size at most O(p(n)2) that simulates a computer (details omitted…) NP M poly-time NP-Completeness CIRCUIT-SAT 18 Cook-Levin Proof We can build a circuit that simulates the verification of x’s membership in M using y. Inputs D Let W be the working storage for D (including registers, such as program counter); let D be given in RAM “machine < p(n) W cells code.” Simulate p(n) steps of D by replicating circuit S for each y step of D. Only input: y. Circuit is satisfiable if and only n x if x is accepted by D with some certificate y Total size is still polynomial: O(p(n)3). NP-Completeness D D W W S Output 0/1 from D S y y x x p(n) steps 19 Some Thoughts about P and NP NP-complete problems live here NP P CIRCUIT-SAT Belief: P is a proper subset of NP. Implication: the NP-complete problems are the hardest in NP. Why: Because if we could solve an NP-complete problem in polynomial time, we could solve every problem in NP in polynomial time. That is, if an NP-complete problem is solvable in polynomial time, then P=NP. Since so many people have attempted without success to find polynomial-time solutions to NP-complete problems, showing your problem is NP-complete is equivalent to showing that a lot of smart people have worked on your problem and found no polynomial-time algorithm. NP-Completeness 20